CN111000294B - Heating method and device of atomizer, computer equipment and storage medium - Google Patents

Abstract

The application relates to a heating method, a heating device, a computer device and a storage medium for an atomizer. The method comprises the following steps: when the trigger operation is detected, acquiring a sampling value of the thermal property of a heating body in the atomizer in real time; judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment; when the atomizer is judged to reach the thermal balance, taking the sampling value of the thermal property of the heating body when the atomizer reaches the thermal balance as a stable value; determining a first protection trigger value of the heating element according to the stable value; and when the sampling value of the thermal property of the heating element is detected to be larger than or equal to the first protection trigger value, stopping heating the heating element. The heating method, the heating device, the computer equipment and the storage medium of the atomizer can prolong the service life of the atomizer.

Description

Heating method and device for atomizer, computer equipment and storage medium

Technical Field

The present application relates to the field of atomizer technologies, and in particular, to a method and an apparatus for heating an atomizer, a computer device, and a storage medium.

Background

With the development of society, various atomizers, such as humidifiers, electronic cigarettes, medical atomizers, and the like, have appeared. In a conventional heating method for an atomizer, a heating body such as a heating liquid or a heating solid is usually added to the atomizer to be heated, so that the heating body is atomized.

However, when the heating body in the conventional atomizer is insufficient, the temperature of the atomizer is easily and rapidly increased, so that the atomizer is in a dry burning state, and the service life of the atomizer is short.

Disclosure of Invention

In view of the above, it is necessary to provide a heating method, a heating apparatus, a computer device, and a storage medium for an atomizer, which can improve the service life.

A method of heating an atomizer, the method comprising:

when the trigger operation is detected, acquiring a sampling value of the thermal property of a heating body in the atomizer in real time;

judging whether the atomizer reaches thermal balance or not according to the sampling value obtained at the current moment;

when the atomizer is judged to reach the thermal balance, taking the sampling value of the thermal property of the heating body when the atomizer reaches the thermal balance as a stable value;

determining a first protection trigger value of the heating element according to the stable value;

and when the sampling value of the thermal property of the heating element is detected to be larger than or equal to the first protection trigger value, stopping heating the heating element.

In one embodiment, the method further comprises:

determining an initial value according to the acquired sampling value;

the determining a first protection trigger value of the heating element according to the stable value includes:

and determining a first protection trigger value of the heating element according to the initial value and the stable value.

In one embodiment, before taking the sampled value of the thermal property of the heat generating body at the time of reaching the thermal equilibrium as a stable value when the nebulizer is judged to reach the thermal equilibrium, the method further includes:

acquiring a reference value and the maximum value of the thermal property of the heating body in the last trigger operation;

determining a second protection trigger value of the heat-generating body thermal property according to the initial value, the reference value and the maximum value of the heat-generating body thermal property of the last trigger operation;

when the sampling value of the thermal property of the heating element is detected to be larger than or equal to the second protection trigger value, stopping heating the heating element;

wherein the reference value is one of a maximum value of the heat-generating body thermal property in the last trigger operation, a stable value of the heat-generating body thermal property in the last trigger operation, and an average value of the heat-generating body thermal property in the last trigger operation.

In one embodiment, the determining whether the nebulizer reaches thermal equilibrium according to the sampling value obtained at the current time includes:

obtaining each sampling value in a first time length based on the current time; the first time comprises a current time;

and when each sampling value in the first time period accords with a first preset rule, judging that the atomizer reaches thermal balance.

In one embodiment, the method further comprises:

when each sampling value in the first time length does not accord with a first preset rule, each sampling value in a second time length is obtained; the second duration is greater than the first duration; the second duration comprises the current time;

and when each sampling value in the second time period accords with a second preset rule, judging that the atomizer reaches thermal balance.

In one embodiment, the method further comprises:

acquiring a reference stable value and a reference protection trigger value;

determining a target parameter according to the reference stable value and the reference protection trigger value;

the determining a first protection trigger value of the heating element according to the initial value and the stable value includes:

and determining a first protection trigger value of the heating element according to the initial value, the stable value and the target parameter.

In one embodiment, the method further comprises:

acquiring a reference stable value and a reference protection trigger value;

determining a target parameter according to the reference stable value and the reference protection trigger value;

the determining a second protection trigger value of the heating element according to the initial value, the reference value and the maximum value of the heating element triggered last time comprises:

and determining a second protection trigger value of the heating element according to the initial value, the reference value, the maximum value of the heating element in the last trigger operation and the target parameter.

In one embodiment, the determining an initial value according to the obtained sampling value includes:

acquiring a calibration value;

when the sampling value is smaller than the calibration value, taking the sampling value smaller than the calibration value as an initial value;

and when the sampling value is greater than or equal to the calibration value, taking the calibration value as an initial value.

A heating device for an atomizer, the device comprising:

the sampling value acquisition module is used for acquiring the sampling value of the thermal property of the heating element in the atomizer in real time when the trigger operation is detected;

the thermal balance judging module is used for judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment;

the stable value determining module is used for taking a sampling value of the thermal property of the heating body when the thermal balance is reached as a stable value when the atomizer is judged to reach the thermal balance;

the first protection trigger value determining module is used for determining a first protection trigger value of the heating element according to the stable value;

and the heating stopping module is used for stopping heating the heating body when the current sampling value of the thermal property is detected to be greater than or equal to the first protection trigger value.

A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor realizes the steps of the above method when executing the computer program.

A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the steps of the above-mentioned method.

According to the heating method and device of the atomizer, the computer equipment and the storage medium, when the trigger operation is detected, the sampling value of the thermal property of the heating body in the atomizer is acquired in real time; judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment; when judging that the atomizer reaches thermal equilibrium, taking a sampling value of the thermal property of the heating body when the atomizer reaches thermal equilibrium as a stable value; determining a first protection trigger value of the heating element according to the stable value; when the atomizer reaches thermal equilibrium, the sampling value of the thermal property of the heating element is stable, and when the sampling value of the thermal property of the heating element is detected to be greater than or equal to the first protection trigger value, the situation that the heating element in the atomizer, namely a heated object for atomization, is insufficient is indicated, so that the heating element is stopped being heated, the dry burning of the atomizer is prevented, and the service life of the atomizer is prolonged; furthermore, the heating method leads a self-learning process, namely a process of acquiring a stable value, when the trigger operation is detected each time, so that the first protection trigger value is dynamically adjusted along with the operation of the atomizer, and then the heating method automatically adapts to an atomization temperature range of a heating body, thereby ensuring that the atomizer accurately and stably works.

Drawings

FIG. 1 is a schematic flow chart of a heating method of an atomizer in one embodiment;

FIG. 2 is a schematic flow chart illustrating a heating process before the thermal equilibrium of the atomizer is reached in one embodiment;

FIG. 3 is a schematic flow chart of a method for heating an atomizer according to another embodiment;

FIG. 4 is a schematic flow chart illustrating the determination of stable, maximum, minimum, and average values after a trigger operation of the nebulizer in one embodiment;

FIG. 5 is a schematic illustration of sample values during thermal equilibrium of an atomizer in one embodiment;

FIG. 6 is a block diagram showing a heating device of the atomizer according to one embodiment;

FIG. 7 is a diagram illustrating an internal structure of a computer device according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

In one embodiment, as shown in fig. 1, there is provided a heating method of an atomizer, comprising the steps of:

and 102, when the trigger operation is detected, acquiring a sampling value of the thermal property of a heating body in the atomizer in real time.

The atomizer refers to an apparatus that heats a heating body to atomize the heating body. Wherein, the heating body can be liquid or solid. An atomizer, such as an electronic cigarette, heats the tobacco tar through the electronic cigarette, thereby forming the tobacco tar into an aerosol. The nebulizer may also be a humidifier, medical nebulizer, or the like.

The atomizer comprises a heating body, and the heating body can be heated through the heating body. The thermal property of the heat generating body may be a resistance value of the heat generating body or a temperature of the heat generating body.

The trigger operation may be a suction operation, a pressing operation, a clicking operation, a sliding operation, or the like, without being limited thereto. For example, when the nebulizer is an electronic cigarette, the triggering operation may be a smoking operation, and when a pressure sensor in the nebulizer detects a change in air pressure, the triggering operation indicates that the smoking operation is detected.

Real-time refers to responding in a short time. Specifically, a preset time period may be acquired, and when the trigger operation is detected, the sampling value of the thermal property of the heating element in the atomizer is acquired at intervals of the preset time period. For example, the preset time period is 200 milliseconds, that is, when the trigger operation is detected, a sample value of the thermal property of the heat generating body in the atomizer is acquired every 200 milliseconds.

And 104, judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment.

It can be understood that when the atomizer reaches thermal equilibrium, the energy input by the atomizer is the same as the energy output by the atomizer, and the heating body in the atomizer can be heated, so that the atomization is continuously and stably carried out.

And 106, when the atomizer reaches the thermal balance, taking the sampling value of the thermal property of the heating body reaching the thermal balance as a stable value.

And 108, determining a first protection trigger value of the heating element according to the stable value.

The first protection trigger value is a threshold value corresponding to a sampled value of the thermal property of the heat generating body after the thermal equilibrium of the nebulizer is reached. And when the sampling value of the heating element is greater than or equal to the first protection trigger value, the shortage of the heating element in the atomizer is indicated.

And step 110, stopping heating the heating element when the sampling value of the thermal property of the heating element is detected to be larger than or equal to the first protection trigger value.

When detecting that the sampling value of heating element thermal property is greater than or equal to first protection trigger value, it is not enough to show the heating member in the atomizer, consequently stops to heat the heating element, avoids making the atomizer carry out dry combustion method because the heating member is not enough.

In one embodiment, when the sampled value of the thermal property of the heat generating body is detected to be greater than or equal to the first protection trigger value, the power supply of the atomizer can be cut off, so that the atomizer stops heating the heat generating body.

In another embodiment, when the sampling value of the thermal property of the heating element is detected to be greater than or equal to the first protection trigger value, the power supply of the heating element can be cut off, and the heating of the heating element can be stopped.

According to the heating method of the atomizer, when the trigger operation is detected, sampling values of the thermal property of the heating body in the atomizer are obtained in real time, and initial values are determined from the obtained sampling values; judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment; when judging that the atomizer reaches thermal equilibrium, taking a sampling value of the thermal property of the heating body when the atomizer reaches thermal equilibrium as a stable value; determining a first protection trigger value of the heating element according to the initial value and the stable value; when the atomizer reaches thermal equilibrium, the sampling value of the thermal property of the heating element is stable, and when the sampling value of the thermal property of the heating element is detected to be greater than or equal to the first protection trigger value, the situation that the heating element in the atomizer, namely a heated object for atomization, is insufficient is indicated, so that the heating element is stopped being heated, the dry burning of the atomizer is prevented, and the service life of the atomizer is prolonged; furthermore, the heating method leads a self-learning process, namely a process of obtaining a stable value, to be introduced when the trigger operation is detected each time, so that the first protection trigger value is dynamically adjusted along with the operation of the atomizer, and then the first protection trigger value is automatically adapted to the atomization temperature range of the heating body, and the atomizer is ensured to accurately and stably work.

In one embodiment, the method further comprises: and determining an initial value according to the acquired sampling value. Determining a first protection trigger value of the heating element according to the stable value, comprising: and determining a first protection trigger value of the heating element according to the initial value and the stable value.

The initial value may be a sampled value of the thermal property of the heating element in the nebulizer acquired for the first time when the trigger operation is detected, may be the smallest sampled value of the acquired predetermined sampled values, or may be the next smallest sampled value of the acquired predetermined sampled values, without being limited thereto.

In one embodiment, as shown in fig. 2, when it is determined that the nebulizer reaches the thermal equilibrium, before taking the sampled value of the thermal property of the heat generating body at the time of the thermal equilibrium as the stable value, the method further includes:

step 202, obtaining a reference value and a maximum value of the thermal property of the heating element of the last trigger operation.

The reference value may be one of a maximum value of the heat-generating body thermal property of the last trigger operation, a stable value of the heat-generating body thermal property of the last trigger operation, and an average value of the heat-generating body thermal property of the last trigger operation. The reference value may also be other values that the user sets as desired, without being limited thereto.

And step 204, determining a second protection trigger value of the heat attribute of the heat generator according to the initial value, the reference value and the maximum value of the heat attribute of the heat generator of the last trigger operation.

The second protection trigger value is a threshold value corresponding to a sampled value of the thermal property of the heat generating body before the nebulizer reaches thermal equilibrium.

And step 206, stopping heating the heating body when the sampling value of the thermal property of the heating body is detected to be larger than or equal to the second protection trigger value.

Before the atomizer reaches thermal balance, when detecting that the sampling value of heating element thermal property is greater than or equal to second protection trigger value, it is not enough to show the heating member in the atomizer, consequently stops to heat the heating element, avoids making the atomizer carry out dry combustion method because the heating member is not enough.

In one embodiment, when the sampled value of the thermal property of the heating element is detected to be greater than or equal to the second protection trigger value, the power supply of the atomizer can be cut off, so that the atomizer stops heating the heating element.

In another embodiment, when the sampling value of the thermal property of the heating element is detected to be greater than or equal to the second protection trigger value, the power supply of the heating element can be cut off, and the heating of the heating element is stopped.

In this embodiment, before the heat-generating body reaches the thermal equilibrium, the second protection trigger value of the heat-generating body thermal property is determined according to the obtained initial value, the reference value and the maximum value of the heat-generating body thermal property of the last trigger operation, and when it is detected that the sampling value of the heat-generating body thermal property is greater than or equal to the second protection trigger value, it indicates that the heated object for atomization in the atomizer is insufficient, so that the heating of the heat-generating body is stopped, the dry burning of the atomizer is prevented, and the service life of the atomizer is prolonged.

It will be appreciated that when the trigger operation is a first trigger operation, i.e. the maximum value of the thermal property of the heat generating body for the last trigger operation is not included in the nebulizer, then a first protection trigger value after the nebulizer has reached thermal equilibrium is determined.

In one embodiment, the atomizer can be an electronic cigarette, and when the cartridge is detected to be inserted into the atomizer, the step of acquiring the sampling value of the thermal property of the heating body in the atomizer in real time is executed; and when the fact that the cigarette cartridge is pulled out of the atomizer is detected, clearing the data stored in the atomizer. Wherein the cartridge may be used to store a heating body, such as tobacco tar.

In one embodiment, as shown in fig. 3, step 302 is performed, and when a trigger operation is detected, step 304 is performed to obtain a sampled value of the thermal property of the heat generating body, and step 306 is performed based on the obtained sampled value to determine whether the thermal equilibrium of the nebulizer has been reached. If yes, executing step 308 to determine a stable value, namely taking the sampling value of the thermal property of the heating element when thermal balance is about to be achieved as the stable value; step 310 is performed to determine a first protection trigger value. Executing step 312, judging whether the current sampling value is greater than or equal to the first protection trigger value, and if so, executing step 314, and stopping heating the heating element; and when the judgment result is negative, ending. In another embodiment, when the current sampling value is less than or equal to the first protection trigger value, the step 312 may be executed continuously.

When the atomizer is judged not to reach the thermal balance, executing step 316, judging whether the current trigger operation is the first trigger operation, and when the current trigger operation is the first trigger operation, executing step 304; if not, that is, if the current trigger operation is not the first trigger operation, determining a second protection trigger value, and executing step 318 to determine whether the current sampling value is greater than or equal to the second protection trigger value; if yes, namely the current sampling value is greater than or equal to the second protection trigger value, executing step 314, and stopping heating the heating element; if not, i.e. the current sampling value is less than or equal to the second protection trigger value, step 304 is executed.

In one embodiment, the reference value is one of a maximum value of the heat-generating body of the last trigger operation, a stable value of the heat-generating body of the last trigger operation, and an average value of the heat-generating bodies of the last trigger operation.

The method for determining the maximum value of the thermal property of the heating body in the last trigger operation comprises the following steps: acquiring a stable value of the thermal property of the heating body in each triggering operation; the maximum stable value among the stable values is used as the maximum value of the thermal property of the heat generating body in the last trigger operation.

In the process of each triggering operation, when the atomizer reaches thermal equilibrium, a sampling value of the thermal property of the heating body when the atomizer reaches thermal equilibrium is obtained and recorded, and the sampling value is taken as a stable value of the triggering operation. And acquiring the last trigger operation and each recorded stable value before the last trigger operation, comparing the stable values, and taking the maximum stable value as the maximum value of the thermal property of the heating body in the last trigger operation.

For example, 4 times of trigger operations exist before the current trigger operation, the stable value of the first trigger operation is 220, the stable value of the second trigger operation is 230, the stable value of the third trigger operation is 210, and the stable value of the fourth, i.e., last, trigger operation is 235, and then the maximum value of the heat generating body thermal property of the last trigger operation is 235.

For another example, 4 times of trigger operations exist before the current trigger operation, the stable value of the first trigger operation is 220, the stable value of the second trigger operation is 230, the stable value of the third trigger operation is 210, and the stable value of the fourth, i.e., last, trigger operation is 213, and then the maximum value of the heat generating body thermal property of the last trigger operation is 230.

In one embodiment, when the thermal equilibrium of the atomizer is reached, the stable value of the thermal property of the heat generating body in the current trigger operation and the maximum value of the thermal property of the heat generating body in the last trigger operation are used as the maximum value of the thermal property of the heat generating body in the current trigger operation, wherein the larger value of the stable value and the maximum value of the thermal property of the heat generating body in the last trigger operation is used as the maximum value of the thermal property of the heat generating body in the current trigger operation.

And when the current trigger operation is the first trigger operation, taking the stable value of the thermal property of the heating element of the current trigger operation as the maximum value of the thermal property of the heating element of the current trigger operation.

For example, when the nebulizer reaches thermal equilibrium in the first trigger operation, a stable value S _ stable1 of the heat generating body thermal property is acquired, and S _ stable1 is taken as the maximum value S _ max of the heat generating body thermal property in the first trigger operation; when the atomizer reaches heat balance in the second triggering operation, a stable value S _ stable2 of the heat attribute of the heat generating body is obtained, when S _ stable2 is larger than S _ stable1, S _ stable2 is used as the maximum value S _ max of the heat attribute of the heat generating body in the second triggering operation, when S _ stable2 is smaller than or equal to S _ stable1, S _ stable1 is used as the maximum value S _ max of the heat attribute of the heat generating body in the second triggering operation, and the like.

The average value of the thermal property of the heating body of the last trigger operation comprises the following steps: acquiring a stable value of the thermal property of the heating body in each triggering operation; an average value is determined based on each of the stable values, and the average value is taken as an average value of the thermal properties of the heat-generating body of the last trigger operation.

And acquiring a stable value of the thermal property of the heating body in each trigger operation, and calculating an average value, wherein the average value is used as the average value of the thermal property of the heating body in the last trigger operation.

And when the last trigger operation is the first trigger operation, taking the stable value of the thermal property of the heating element of the last trigger operation as the average value of the thermal property of the heating element of the last trigger operation.

Further, when the statistical stable value reaches the threshold value, the average value of the heat attributes of the heat generating body is determined, so that the average value can be more accurate.

In one embodiment, determining whether the nebulizer reaches thermal equilibrium based on the sampling value obtained at the current time includes: obtaining each sampling value in the first duration based on the current time; the first time comprises the current time; and when each sampling value in the first time period accords with a first preset rule, judging that the atomizer reaches thermal balance.

The first time period can be set according to the needs of the user.

In one embodiment, the first predetermined rule may be that the sample values within the first length of time are the same. For example, the current time is 19 hours, 5 minutes, 10 seconds and 20 milliseconds, the nebulizer acquires the sampling value of the thermal property of the heating element in the nebulizer every 200 milliseconds, the first time length may be an integral multiple of 200 milliseconds, for example, 600 milliseconds, 4 sampling values may be acquired in 19 hours, 5 minutes, 10 seconds, 20 milliseconds to 19 hours, 5 minutes, 10 seconds and 620 milliseconds, and when the 4 sampling values are the same, it may be determined that the nebulizer reaches thermal equilibrium.

In another embodiment, the first predetermined rule may be that the difference of the sampling values in the first time period is within a preset range. For example, the current time is 19 hours, 5 minutes, 10 seconds and 20 milliseconds, the sampling value of the thermal property of the heating element in the nebulizer is acquired every 200 milliseconds by the nebulizer, the first time length may be an integral multiple of 200 milliseconds, for example, 600 milliseconds, 4 sampling values may be acquired in 19 hours, 5 minutes, 10 seconds, 20 milliseconds to 19 hours, 5 minutes, 10 seconds and 620 milliseconds, which are 578,579,580,578 respectively, and the preset range is 10, and the difference value of each sampling value in the first time length is in the preset range, so that it may be determined that the nebulizer reaches thermal equilibrium.

In this embodiment, each sampling value in the first duration is obtained at the current moment, and when the sampling value in the first duration meets the first rule, it can be more accurately determined that the thermal balance of the atomizer is achieved.

In one embodiment, the method further comprises: when each sampling value in the first time length does not accord with a first preset rule, each sampling value in the second time length is obtained; the second duration is greater than the first duration; the second duration comprises the current time; and when each sampling value in the second time period accords with a second preset rule, judging that the atomizer reaches thermal balance.

The second predetermined rule may be set according to the user's needs.

In one embodiment, the second predetermined rule may be that the sample values within the second time period increase one by one in chronological order, and the largest difference in the differences between two adjacent sample values within the second time period is smaller than the difference threshold.

In another embodiment, the second predetermined rule may be that the sampling values in the second time period are sequentially increased in time and then kept unchanged.

In one embodiment, the method further comprises: when the sampling values in the first time length are different, acquiring the sampling values in the second time length; the second duration is greater than the first duration; the second duration comprises the current time; when the sampling values in the second time length are increased one by one according to the time sequence, obtaining the difference value of two adjacent sampling values in the second time length; determining the maximum difference value from the difference values; and when the maximum difference is smaller than the difference threshold value, judging that the atomizer reaches thermal balance.

The second duration can be set according to the user requirement, and the second duration is longer than the first duration. For example, the current time is 19 hours, 5 minutes, 10 seconds, and 20 milliseconds, and the nebulizer acquires a sample value of the thermal property of the heat generating body in the nebulizer every 200 milliseconds. When the samples in the first time period are different, the samples in the second time period are obtained, the second time period may also be an integer multiple of 200 ms, for example, 800 ms, and 5 samples, 210,220,235,240,252,260, may be obtained at 19 h, 5 min, 10 s, 20 ms to 19 h, 5 min, 10 s, 820 ms. And (3) increasing the sampling values within 800 milliseconds of the second time length one by one according to the time sequence, determining the difference values of two adjacent sampling values, namely 10,15,5,12 and 8, wherein the difference threshold value is 20, and judging that the atomizer reaches thermal equilibrium if the maximum difference value 15 is less than the difference threshold value 20.

In this embodiment, when the sampling values in the first time period are different, the sampling values in the first time period are obtained, and when the sampling values in the second time period are increased one by one according to the time sequence, and the maximum difference value between two adjacent sampling values is smaller than the threshold, it indicates that the atomizer is in a stable state, and it can be more accurately determined that the atomizer reaches thermal balance.

In another embodiment, when the sampling values in the first time period are different, the sampling values in the second time period are obtained; the second duration is greater than the first duration; the second duration comprises the current time; and when the sampling values in the second time period are increased one by one according to the time sequence and then are kept unchanged, judging that the atomizer reaches thermal balance.

When the sampling values in the second time period are increased one by one according to the time sequence and then are kept unchanged, namely the data of two stages before reaching the thermal equilibrium and after reaching the thermal equilibrium are included in the second time period, and when the sampling values are kept unchanged, the thermal equilibrium of the atomizer is reached.

In this embodiment, when the sampling values in the first time period are different, the sampling values in the second time period are obtained, and when the sampling values in the second time period meet the second predetermined rule, the thermal balance of the atomizer is reached before the thermal balance, so that the thermal balance of the atomizer can be more accurately determined.

In one embodiment, as shown in fig. 4, in step 402, when the trigger operation is detected, the sampled value of the thermal property of the heating element in the nebulizer is obtained in real time, that is, step 404 and step 406 are performed, and whether the trigger time length is an integral multiple of the preset time length is determined, when the trigger time length is determined to be an integral multiple of the preset time length, the sampled value of the thermal property of the heating element is obtained, and when the trigger time length is determined to be an integral multiple of the preset time length, step 404 is continuously performed. The trigger duration refers to a duration between the current time and the trigger operation time.

Executing step 408, and judging whether the trigger time length is greater than or equal to the first time length; if yes, go to step 410, determine whether each sample value in the first duration meets the first predetermined rule; when the determination is yes, step 412 is performed, and the nebulizer reaches thermal equilibrium, determining a stable value. When the trigger duration is determined to be less than the first duration, step 404 is performed. When the sampling values within the first time period do not meet the first predetermined rule, executing step 414 to determine whether the trigger time period is greater than or equal to the second time period; if yes, go to step 416, determine whether each sample value in the second duration meets the second predetermined rule; when the determination is yes, step 412 is performed and the nebulizer reaches thermal equilibrium, determining a stable value.

When the trigger duration is less than the second duration, step 404 is performed. When it is determined that the respective sample values within the second time period do not meet the second predetermined rule, step 404 is executed. When the nebulizer reaches thermal equilibrium, step 418 may be performed to determine the maximum, minimum, and average values of the thermal properties of the heat generating body.

In one embodiment, the method further comprises: acquiring a reference stable value and a reference protection trigger value; and determining the target parameter according to the reference stable value and the reference protection trigger value. Determining a first protection trigger value of the heating element according to the initial value and the stable value, comprising: and determining a first protection trigger value of the heating element according to the initial value, the stable value and the target parameter.

The reference stability value is a predicted empirical value for the nebulizer at thermal equilibrium. The reference protection trigger value is a threshold value of a predicted thermal property of a heat generating body in the nebulizer.

For example, when the atomizer is an electronic cigarette, the heating body in the electronic cigarette is tobacco tar, and according to the characteristics of the tobacco tar, when the tobacco tar is atomized and the atomizer reaches thermal equilibrium, the sampling value of the thermal property of the heating body may be 250 ℃ to 290 ℃, a reference stable value such as 270 ℃ may be determined, a reference protection trigger value is 320 ℃, and then the value range of the K value may be 0.1 to 0.2.

Further, a candidate interval of the target parameter may be obtained, the candidate parameter may be determined according to the reference stable value and the reference protection trigger value, and when the candidate parameter is within the candidate interval, the candidate parameter may be used as the target parameter.

For example, the determined candidate region may be between 0.1 and 0.2, and when the candidate parameter determined according to the parameter stable value and the parameter protection trigger value is between 0.1 and 0.2, the candidate parameter may be taken as the target parameter.

In this embodiment, the target parameter is determined according to the obtained reference stable value and the reference protection trigger value, and a more accurate first protection trigger value can be determined according to the initial value, the stable value, and the target parameter.

In one embodiment, the method further includes obtaining a reference stable value and a reference protection trigger value; and determining the target parameter according to the reference stable value and the reference protection trigger value. Determining a second protection trigger value of the heating element according to the initial value, the reference value and the maximum value of the heating element which is triggered and operated last time, wherein the second protection trigger value comprises the following steps: and determining a second protection trigger value of the heating element according to the initial value, the reference value, the maximum value of the heating element which is triggered and operated last time and the target parameter.

The reference stability value is a predicted empirical value for the nebulizer at thermal equilibrium. The reference protection trigger value is a predicted empirical threshold for the thermal properties of the heat generating body in the nebulizer.

For example, when the atomizer is an electronic cigarette, the heating body in the electronic cigarette is tobacco tar, and according to the characteristics of the tobacco tar, when the tobacco tar is atomized and the atomizer reaches thermal equilibrium, the sampling value of the thermal property of the heating body may be 250 ℃ to 290 ℃, a reference stable value such as 270 ℃ may be determined, a reference protection trigger value is 320 ℃, and then the value range of the K value may be 0.1 to 0.2.

Further, a candidate interval of the target parameter may be obtained, the candidate parameter may be determined according to the reference stable value and the reference protection trigger value, and when the candidate parameter is within the candidate interval, the candidate parameter may be used as the target parameter.

For example, the determined candidate region may be between 0.1 and 0.2, and when the candidate parameter determined according to the parameter stable value and the parameter protection trigger value is between 0.1 and 0.2, the candidate parameter may be taken as the target parameter.

In this embodiment, the target parameter is determined according to the obtained reference stable value and the reference protection trigger value, and a more accurate second protection trigger value can be determined according to the initial value, the reference value, the maximum value of the heating element triggered and operated last time, and the target parameter.

In one embodiment, determining an initial value from the acquired sample values comprises: acquiring a calibration value; when the sampling value is smaller than the calibration value, taking the sampling value smaller than the calibration value as an initial value; and when the sampling value is greater than or equal to the calibration value, taking the calibration value as an initial value. The sampling value may be a sampling value of a thermal property of a heating element in the nebulizer, which is acquired for the first time when the trigger operation is detected, or may be a minimum sampling value of the acquired predetermined sampling values, or may be a next minimum sampling value of the acquired predetermined sampling values, which is not limited thereto.

The initial value refers to a sampling value of the thermal property of the atomizer heating element at normal temperature. The calibration value is a predicted value of the thermal property of the atomizer heating body at normal temperature.

It will be appreciated that the sampled value of the thermal property of the heat generating body is small at ambient temperature prior to the operation of triggering the nebulizer, and is large when the nebulizer reaches thermal equilibrium. Fig. 5 shows sampled values of the thermal properties of the heat generating body in the atomizer during one triggering operation. In the process of one triggering operation, the sampling value of the thermal property of the heating element is increased firstly and then reaches stability, 502 is the point when the atomizer reaches stability, and the sampling value corresponding to the point is a stable value.

When the trigger operation is detected, when the sampling value of the thermal property of the heating body in the atomizer acquired in the starting time period is greater than or equal to the calibration value, the fact that the heating body is in a cooling state after the atomizer reaches thermal balance through the trigger operation before a period of time is shown, the sampling value of the thermal property of the heating body is still higher than the calibration value of the heating body at normal temperature is still shown, and therefore the calibration value serves as an initial value.

When the trigger operation is detected, when the sampling value of the thermal property of the heating body of the atomizer is smaller than the calibration value, the sampling value can be used as the sampling value of the thermal property of the heating body at normal temperature. Therefore, the sampling value smaller than the calibration value is used as the initial value.

In this embodiment, a calibration value is obtained, and a sampling value is compared with the calibration value, so that a more accurate initial value can be determined.

It should be understood that although the steps in the flowcharts of fig. 1 and 2 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least some of the steps in fig. 1 and 2 may include multiple sub-steps or multiple stages that are not necessarily performed at the same time, but may be performed at different times, and the order of performing the sub-steps or stages is not necessarily sequential, but may be performed alternately or alternately with other steps or at least some of the sub-steps or stages of other steps.

In one embodiment, as shown in fig. 6, there is provided a heating device 600 of an atomizer, comprising: a sample value acquisition module 602, a thermal balance determination module 604, a stable value determination module 606, a first protection trigger value determination module 608, and a stop heating module 610, wherein:

and the sampling value acquisition module 602 is configured to acquire a sampling value of a thermal property of a heater in the nebulizer in real time when the trigger operation is detected.

And a thermal balance determining module 604, configured to determine whether the atomizer reaches thermal balance according to the sampling value obtained at the current time.

And a stable value determining module 606, configured to, when it is determined that the nebulizer reaches the thermal equilibrium, take the sampling value of the thermal property of the heat generating body at the time of the thermal equilibrium as a stable value.

And a first protection trigger value determining module 608, configured to determine a first protection trigger value of the heating element according to the stable value.

And the heating stopping module 610 is used for stopping heating the heating element when the current sampling value of the thermal property is detected to be greater than or equal to the first protection trigger value.

When the heating device of the atomizer detects the trigger operation, the sampling value of the thermal property of the heating body in the atomizer is acquired in real time; judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment; when the atomizer is judged to reach the thermal equilibrium, taking a sampling value of the thermal property of the heating body when the atomizer reaches the thermal equilibrium as a stable value; determining a first protection trigger value of the heating element according to the stable value; when the atomizer reaches thermal equilibrium, the sampling value of the thermal property of the heating element is stable, and when the sampling value of the thermal property of the heating element is detected to be greater than or equal to the first protection trigger value, the situation that the heating element in the atomizer, namely a heated object for atomization, is insufficient is indicated, so that the heating element is stopped being heated, the dry burning of the atomizer is prevented, and the service life of the atomizer is prolonged; furthermore, the heating method leads a self-learning process, namely a process of obtaining a stable value, to be introduced when the trigger operation is detected each time, so that the first protection trigger value is dynamically adjusted along with the operation of the atomizer, and then the first protection trigger value is automatically adapted to the atomization temperature range of the heating body, and the atomizer is ensured to accurately and stably work.

In one embodiment, the heating device 600 of the nebulizer further comprises an initial value determining module for determining an initial value according to the acquired sampling value. Determining a first protection trigger value of the heating element according to the stable value, comprising: and determining a first protection trigger value of the heating element according to the initial value and the stable value.

In one embodiment, the stop heating module 610 is further configured to obtain a reference value and a maximum value of the thermal property of the heating element of the last trigger operation; determining a second protection trigger value of the thermal attribute of the heating element according to the initial value, the reference value and the maximum value of the thermal attribute of the heating element of the last trigger operation; and when the sampling value of the thermal property of the heating body is detected to be larger than or equal to the second protection trigger value, stopping heating the heating body.

In one embodiment, the reference value is one of a maximum value of the heat-generating body thermal property of the last trigger operation, a steady value of the heat-generating body thermal property of the last trigger operation, and an average value of the heat-generating body thermal property of the last trigger operation. The method for determining the maximum value of the thermal property of the heating body in the last trigger operation comprises the following steps: acquiring a stable value of the thermal property of the heating body in each triggering operation; the maximum stable value among the stable values is used as the maximum value of the thermal property of the heat generating body in the last trigger operation. The average value of the thermal property of the heating body of the last triggering operation comprises the following steps: acquiring a stable value of the thermal property of the heating body in each triggering operation; an average value is determined based on each of the stable values, and the average value is taken as an average value of the thermal properties of the heat-generating body of the last trigger operation.

In one embodiment, the thermal balance determining module 604 is further configured to obtain each sampling value within the first duration based on the current time; the first time comprises the current time; and when each sampling value in the first time period accords with a first preset rule, judging that the atomizer reaches thermal balance.

In one embodiment, the thermal balance determining module 604 is further configured to obtain each sample value in the second time period when each sample value in the first time period does not meet the first predetermined rule; the second duration is greater than the first duration; the second duration comprises the current time; and when each sampling value in the second time period accords with a second preset rule, judging that the atomizer reaches thermal balance.

In one embodiment, the heating device of the atomizer further includes a target parameter determining module, configured to obtain a reference stable value and a reference protection trigger value; and determining the target parameter according to the reference stable value and the reference protection trigger value. Determining a first protection trigger value of the heating element according to the initial value and the stable value, comprising: and determining a first protection trigger value of the heating element according to the initial value, the stable value and the target parameter.

In one embodiment, the target parameter determining module is further configured to obtain a reference stable value and a reference protection trigger value; and determining the target parameter according to the reference stable value and the reference protection trigger value. Determining a second protection trigger value of the heating element according to the initial value, the reference value and the maximum value of the heating element which is triggered and operated last time, wherein the second protection trigger value comprises the following steps: and determining a second protection trigger value of the heating element according to the initial value, the reference value, the maximum value of the heating element which is triggered and operated last time and the target parameter.

In an embodiment, the sampling value obtaining module 602 is further configured to obtain a calibration value; when the sampling value is smaller than the calibration value, taking the sampling value smaller than the calibration value as an initial value; and when the sampling value is greater than or equal to the calibration value, taking the calibration value as an initial value.

For specific definitions of the heating means of the atomizer, reference may be made to the above definitions of the heating means of the atomizer, which are not described in detail here. The various modules in the heating device of the atomizer described above may be implemented in whole or in part by software, hardware, and combinations thereof. The modules can be embedded in a hardware form or independent of a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, which may be a terminal, and its internal structure diagram may be as shown in fig. 7. The computer device includes a processor, a memory, a network interface, a display screen, and an input device connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system and a computer program. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a method of heating a nebulizer. The display screen of the computer equipment can be a liquid crystal display screen or an electronic ink display screen, and the input device of the computer equipment can be a touch layer covered on the display screen, a key, a track ball or a touch pad arranged on the shell of the computer equipment, an external keyboard, a touch pad or a mouse and the like.

Those skilled in the art will appreciate that the architecture shown in fig. 7 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, a computer device is provided, comprising a memory in which a computer program is stored and a processor which, when executing the computer program, carries out the steps of the above-described method of heating a nebulizer.

In an embodiment, a computer-readable storage medium is provided, on which a computer program is stored which, when being executed by a processor, carries out the steps of the above-mentioned method of heating a nebulizer.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database, or other medium used in the embodiments provided herein may include non-volatile and/or volatile memory, among others. Non-volatile memory can include read-only memory (ROM), Programmable ROM (PROM), Electrically Programmable ROM (EPROM), Electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), Dynamic RAM (DRAM), Synchronous DRAM (SDRAM), Double Data Rate SDRAM (DDRSDRAM), Enhanced SDRAM (ESDRAM), Synchronous Link DRAM (SLDRAM), Rambus Direct RAM (RDRAM), direct bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

All possible combinations of the technical features in the above embodiments may not be described for the sake of brevity, but should be considered as being within the scope of the present disclosure as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A method of heating an atomizer comprising:

when the trigger operation is detected, acquiring a sampling value of the thermal property of a heating body in the atomizer in real time;

judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment;

when the atomizer is judged to reach the thermal balance, taking the sampling value of the thermal property of the heating body when the atomizer reaches the thermal balance as a stable value;

determining a first protection trigger value of the heating element according to the stable value;

when the sampling value of the thermal property of the heating element is detected to be larger than or equal to the first protection trigger value, stopping heating the heating element;

when judging that the atomizer reaches thermal equilibrium, before the sampling value of the heating element thermal property when reaching thermal equilibrium is taken as a stable value, the method further comprises the following steps:

determining an initial value according to the acquired sampling value; acquiring a reference value and the maximum value of the thermal property of the heating body in the last trigger operation; wherein the reference value is one of a maximum value of the heat-generating body thermal property of the last trigger operation, a stable value of the heat-generating body thermal property of the last trigger operation, and an average value of the heat-generating body thermal property of the last trigger operation;

determining a second protection trigger value of the thermal attribute of the heating element according to the initial value, the reference value and the maximum value of the thermal attribute of the heating element in the last trigger operation; wherein the second protection trigger value is a threshold value corresponding to a sampled value of the thermal property of the heat generating body before the nebulizer reaches thermal equilibrium;

and when the sampling value of the thermal property of the heating body is detected to be larger than or equal to the second protection trigger value, stopping heating the heating body.

2. The method according to claim 1, wherein the determining a first protection trigger value of the heat generating body according to the stable value includes:

and determining a first protection trigger value of the heating element according to the initial value and the stable value.

3. The method of claim 1, wherein said determining whether the nebulizer is in thermal equilibrium based on the sample value obtained at the current time comprises:

obtaining each sampling value in a first time length based on the current time; the first time comprises a current time;

and when each sampling value in the first time period accords with a first preset rule, judging that the atomizer reaches thermal balance.

4. The method of claim 3, further comprising:

when each sampling value in the first time length does not accord with a first preset rule, each sampling value in a second time length is obtained; the second duration is greater than the first duration; the second duration comprises the current time;

and when each sampling value in the second time period accords with a second preset rule, judging that the atomizer reaches thermal balance.

5. The method of claim 2, further comprising:

acquiring a reference stable value and a reference protection trigger value;

determining a target parameter according to the reference stable value and the reference protection trigger value;

the determining a first protection trigger value of the heating element according to the initial value and the stable value includes:

and determining a first protection trigger value of the heating element according to the initial value, the stable value and the target parameter.

6. The method of claim 1, further comprising:

acquiring a reference stable value and a reference protection trigger value;

determining a target parameter according to the reference stable value and the reference protection trigger value;

the determining a second protection trigger value of the heating element according to the initial value, the reference value and the maximum value of the heating element of the last trigger operation comprises:

and determining a second protection trigger value of the heating element according to the initial value, the reference value, the maximum value of the heating element in the last trigger operation and the target parameter.

7. The method of claim 1, wherein determining an initial value based on the obtained sample value comprises:

acquiring a calibration value;

when the sampling value is smaller than the calibration value, taking the sampling value smaller than the calibration value as an initial value;

and when the sampling value is greater than or equal to the calibration value, taking the calibration value as an initial value.

8. A heating device for an atomizer, said device comprising:

the sampling value acquisition module is used for acquiring the sampling value of the thermal property of the heating element in the atomizer in real time when the trigger operation is detected;

the thermal balance judging module is used for judging whether the atomizer reaches thermal balance or not according to the sampling value acquired at the current moment;

the stable value determining module is used for taking a sampling value of the thermal property of the heating body when the thermal balance is reached as a stable value when the atomizer is judged to reach the thermal balance;

the first protection trigger value determining module is used for determining a first protection trigger value of the heating element according to the stable value;

the heating stopping module is used for stopping heating the heating body when the current sampling value of the thermal attribute is detected to be larger than or equal to the first protection trigger value;

the initial value determining module is used for determining an initial value according to the acquired sampling value;

the heating stopping module is also used for acquiring a reference value and the maximum value of the thermal property of the heating body in the last triggering operation; wherein the reference value is one of a maximum value of the heat-generating body thermal property of the last trigger operation, a stable value of the heat-generating body thermal property of the last trigger operation, and an average value of the heat-generating body thermal property of the last trigger operation; determining a second protection trigger value of the heat-generating body thermal property according to the initial value, the reference value and the maximum value of the heat-generating body thermal property of the last trigger operation; wherein the second protection trigger value is a threshold value corresponding to a sampled value of the thermal property of the heat generating body before the nebulizer reaches thermal equilibrium; and when the sampling value of the thermal property of the heating body is detected to be larger than or equal to the second protection trigger value, stopping heating the heating body.

9. A computer device comprising a memory and a processor, the memory storing a computer program, wherein the processor implements the steps of the method of any one of claims 1 to 7 when executing the computer program.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 7.

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